cmpe 150 – winter 2009
DESCRIPTION
CMPE 150 – Winter 2009. Lecture 1 January 5, 2009 P.E. Mantey. CMPE 150 -- Introduction to Computer Networks. Instructor: Patrick Mantey [email protected] http://www.soe.ucsc.edu/~mantey/ Office: Engr. 2 Room 595J Office hours: Tuesday 3-5 PM TA: Anselm Kia - PowerPoint PPT PresentationTRANSCRIPT
CMPE 150 – Winter 2009
Lecture 1
January 5, 2009
P.E. Mantey
CMPE 150 -- Introduction to Computer Networks
Instructor: Patrick Mantey [email protected] http://www.soe.ucsc.edu/~mantey/
Office: Engr. 2 Room 595J Office hours: Tuesday 3-5 PM TA: Anselm Kia Web site: http://www.soe.ucsc.edu/classes/cmpe150/Winter09/
Text: Tannenbaum: Computer Networks (4th edition – available in bookstore, etc. )
TextTannenbaum: Computer
Networks (Prentice-Hall) 4th edition
Reference
Stallings: Data and Computer Communications (Prentice Hall)
Other Networking Courses CE 151 Network Administration CE 152 Protocols CE 156 Network Programming CE 107 Stochastic System Analysis EE 103 Signals and Systems CE 154 Data Communication CE 153 Digital Signal Processing EE 151 Communications Systems CE 108 Data Compression CE 163 Multimedia CS 111 Operating Systems CE 80N General Education on Networks
Syllabus
Grading Midterms 40% (20% each) Class quizzes 25% * Final Exam 35 % Problem Assignments 0 to -10 % **
* Plan for four (unannounced) 15 minute in-class quizzes. Lowest score will be dropped. No makeup for missed quizzes. In class quizzes will aggregate to count 25% of grade – thus a bit more than another mid-term.
** Problem assignments to be turned in – and only those on time will be credited. Students will start with full credit for problem assignments – but if not completed with good performance up to 10 % deduction will be made from total exam score.
No credit for work that is not your own.
Academic Integrity
http://www.ucsc.edu/academics/academic_integrity/index.html
http://www.cse.ucsc.edu/advising/undergraduate/pdf/soehandbook0203.pdf
"All members of the UCSC community have an explicit responsibility to foster an environment of trust, honesty, fairness, respect, and responsibility. All members of the university community are expected to present as their original work only that which is truly their own. All members of the community are expected to report observed instances of cheating, plagiarism, and other forms of academic dishonesty in order to ensure that the integrity of scholarship is valued as preserved at UCSC.
In the event a student is found in violation of the UCSC Academic Integrity policy, he or she may face both academic sanctions imposed by the instructor of the course and disciplinary sanctions imposed either by the provost of his or her college or by the Academic Tribunal convened to hear the case. Violations of the Academic Integrity policy can result in expulsion from the university and a permanent notation on the student's transcript.”
Source: The Navigator http://reg.ucsc.edu/navigator/chapter1.html
Some Current Topics Digital TV
http://www.spectrum.ieee.org/oct05/1911 Ultra Wideband WiMedia Standard
IEEE Signal Processing September 2008, pp. 115-118
New Cisco Edge Routerhttp://www.eetimes.com/news/latest/showArticle.jhtml?articleID=206902487
HD videoconferencing Cloud Computing / Networked Attached
Storage Home Media Center (Windows Vista, etc.)
NAS
Network Attached Storage
Computer Networking
Computer to peripheral Serial (RS232, USB,…) Parallel
Computer Networking
Computer to peripheral Computer to computer Computer to network (of
computers)
Computer Networking
Computer to peripheral Serial (RS232, USB,…) Parallel
Computer Networking
Computer to peripheral Serial
RS232 USB bluetooth infrared
Parallel
Computer Networking
Computer to Computer hard wire (“null modem”) modem to modem client-server
Computer Networking
Computer to Network (of computers) Ethernet 802.11 Internet (TCP/IP)
Local Area Networks
Smaller scope Building or small campus
Usually owned by same organization as attached devices
Data rates much higher Early days – “broadcast” systems Now switched
Local Area Networks
Ethernet Token-ring FDDI Fiber Channel
PC Network View
Ethernet 802.11 (a,b,g,n) Bluetooth Infrared Serial Parallel USB Modem
My PC
USB Network
Networking TasksTransmission system utilization
Addressing
Interfacing Routing
Signal generation Recovery
Synchronization Message formatting
Exchange management
Security
Error detection and correction
Network management
Flow control
A Communications Model Source
generates data to be transmitted Transmitter
Converts data into transmittable signals Transmission System
Carries data Receiver
Converts received signal into data Destination
Takes incoming data
Simplified Communications Model - Diagram
Stallings, Fig. 1.1
Key Tasks Transmission System Utilization Interfacing Signal Generation Synchronization Exchange Management Error detection and correction Addressing and routing Recovery Message formatting Security Network Management
Simplified Data Communications Model
Stallings, Fig. 1.2
Networking
Point to point communication not usually practical Devices are too far apart Large set of devices would need
impractical number of connections Solution is a communications network
Local Area Network (LAN) Wide Area Network (WAN)
Simplified Network Model
From Stallings –Ch.1 6th ed.
Wide Area Networks
Large geographical area Crossing public rights of way Rely in part on common carrier circuits Alternative technologies
Circuit switching Packet switching Frame relay Asynchronous Transfer Mode (ATM)
Two Network Views
Circuit Switching Telephone circuits
Packet Switching ARPA net TCP/IP
Circuit Switching
Dedicated communications path established for the duration of the conversation
Packet Switching
Data sent out of sequence Small chunks (packets) of data at a
time Packets passed from node to node
between source and destination Used for terminal to computer and
computer to computer communications
Integrated Services Digital Network
ISDN Designed to replace public telecom
system Wide variety of services Entirely digital domain
DSL
Digital Subscriber Line Uses POTS to “Central Office”
Assymetric DSL (ADSL) Different “up” and “down” speeds e.g.3000/500 Kbps
Frame Relay
Packet switching systems have large overheads to compensate for errors
Modern systems are more reliable Errors can be caught in end system Most overhead for error control is
stripped out
Asynchronous Transfer Mode
ATM Evolution of frame relay Little overhead for error control Fixed packet (called cell) length Anything from 10Mbps to Gbps Constant data rate using packet
switching technique